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Dr. Dorin ILES ([email protected]) FISITA 2008September 14-19, Munich, Germany
Automotive Electric DrivesAn Overview
Dr. Dorin ILES
R&D Laboratory for Electric Drives
ebm-papst St. Georgen
Dr. Dorin ILES ([email protected]) 2 / 32
Targets
• Overview of high performance automotive electric drives
• Overview of permanent magnet synchronous motor (PMSM) drives as one of the most competitive technology
Dr. Dorin ILES ([email protected]) 3 / 32
Contents
I. Introduction• Importance of electric actuation in automotive• Automotive applications and their demands on electric drives• Competing electric drives technologies
II. PMSM drives• Motor types and topologies• Electromagnetic design aspects• Materials, construction and manufacturing technologies• Fundamental motor control issues
III. Case study• Sinusoidal vs. trapezoidal PMSM for active front steering
IV. Conclusion
Dr. Dorin ILES ([email protected]) 4 / 32
IntroductionImportance of electric actuation in automotive
• Clear trend in the automotive industry to use more electric drive systems in order to satisfy the demands for
• lower fuel consumption and lower pollution level• higher vehicle performance (higher comfort, dynamic behaviour, etc.)
• Features of electric actuation• proven technology• high reliability• high efficiency of the energy conversion• precise controllability of the energy flow
Dr. Dorin ILES ([email protected]) 5 / 32
IntroductionDrastic growing of vehicular electric load demands - up to 10 kW
Consequence: higher voltage levels become mandatory12/42/...288/... V
Alternator/RectifierICE
B136V energy storage system
42V DC bus
Bi-directional power
converter
Battery charge/discharge unit
Battery charge/discharge unit
14V DC bus
DC/DCconverter
42V-loads
14V-loads
36V battery
B212V energy storage system
12V battery
Alternator/Rectifier
ICE
Energy storage system
12 Vbattery
Charging system
Main bus
Dashboard control
Conventional vs. advanced power system architecture
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IntroductionEvolution of the costs of electric/electronic equipment of a car
Ratio of electric/electronic cost (E-Cost) to the gross cost (G-Cost) of a car
05
101520253035
1978 1987 1992 1995 1998 2002 2006
Time [Year]
E-C
ost/
G-C
ost [
%]
c
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IntroductionSchematic overview of high performance automotive applications
SteeringHVAC
Fuel Cell Air Compressor
Variable Valve Timing
Throttle-by-wire
Clutch/Shift
Engine Cooling
Starter/ Generator
Traction
Variable Transmission
Turbocharging
BrakingSuspension
Damping Stabilization
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IntroductionSteering systems - classification
Manual steering
mechanical
MS
hydraulicalelectrical
Power-assisted steering
EPAS-column EPAS-pinion
EPAS-rack
HPAS EHPAS
EAS-HPASEPAS-dual-pinion
Full power steering(steer-by-wire)
electricalhydraulical
HPS EPS
EHPS
Steering parameters (steering torque and steering angle)§ torque assistance§ angle assistance
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IntroductionPower assisted steering systems (torque assistance)
Torque sensor
Electric motor
Gearbox
Motor shaft position and speed sensor
Powerend-stage
ICEcontrol
Battery Currentmeasurement
Sensor evaluation
Steering function
Key performance parameters> high torque density> very low cogging torque
(below 20 mNm peak-to-peak)> low torque pulsations> low acoustic noise> high energy efficiency
Candidates• sinusoidal vector current controlled PMSM - only proper candidate• lower demanded peak torque - induction motor (poor energy efficiency)
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IntroductionActive steering systems (angle assistance)
- rack stroke
- steer angle
- steering wheel steer angle
- steer torque
- rack stroke force
- steering wheel steer torque
sT
sδ
swT
swδ
srF
rs
hydraulic actuator
electromechanical actuatorgearbox
fwδ - front wheel steer angle
Candidate• sinusoidal vector current controlled PMSM
Key performance parameters• high torque density• very low cogging torque
(below 20 mNm peak-to-peak)
• low torque pulsations• low acoustic noise
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IntroductionBraking systems
Candidate• trapezoidal PMSM
Key performance parameters• high torque density• high temperature resistance
Wedge brake
Brake disc
Friction pads
WedgeCaliper
ω
Fw
FN
Dr. Dorin ILES ([email protected]) 12 / 32
IntroductionHigh-speed automotive applications - specification and competing technologies
IM, PMSM, SR120000600001Electrical assisted turbocharger
PMSM, SR>>50000.955Engine cooling systems (electric water pump)
PMSM140001200011Air compressor for fuel cells
PMSM17000150002.5Compressor for air conditioner
Competing motortechnologies
nmax [rpm]nbase [rpm]Tpeak [Nm]Application
Dr. Dorin ILES ([email protected]) 13 / 32
IntroductionAutomotive electric drives: torque-speed demands
HVAC
FC-ACEPAS
EAFSEMB
SBW
EG
EHAS
EMAS
EAT
VVT
SGEV
HEV
0
1
10
100
1000
1 10 100 1000 10000 100000
Base speed [rpm]
T_pe
ak [N
m]
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IntroductionAutomotiveutomotive requirements, constraints and implications for electric actuatirequirements, constraints and implications for electric actuation systemson systems
Technical and economical parameters:
• high reliability• high energy efficiency• low costs• compact size• low weight• variable speed control in wide torque-speed ranges• low acoustic noise level• long life cycle
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IntroductionCompeting electric drives technologies for automotive applications
• permanent magnet brushed dc (DC)
• induction (IM)
• permanent magnet trapezoidal (BLDC)
• permanent magnet sinusoidal (BLAC)
• switched-reluctance (SR)
• reluctance synchronous (RS)
DC
IM
BLDC
BLAC
SR RS
0
1
2
3
4
5
6
7
8
9
10
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PMSM drives
•For high performance automotive applications the PMSM represent one of the best candidates
PMSM advantages• high efficiency (in rotor - no copper losses and very low iron losses)• high torque density due to the permanent magnet excitation
PMSM drawbacks• high cost of the permanent magnets• risk of demagnetization at high temperature• increased effort for permanent magnet fixture on/in rotor• additional control effort for field weakening or advance angle control
The technical advantages of the PMSM determined in the last decade the extension of their area of application in the automotive industry
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PMSM drives technologiesClassification based on the shape of back-EMF and excitation currents
0 60 120 180 240 300 360-1.5
-1
-0.5
0
0.5
1
1.5
i
e
sinusoidal machine (BLAC) and control trapezoidal machine (BLDC) and control
3phPMSMVDC
Drive power end
stage
Drive control
position feedback
currents feedback
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0 60 120 180 240 300 360-1.5
-1
-0.5
0
0.5
1
1.5
i
e
PMSM drives technologies BLAC motors and drives
• sinusoidal back-EMF shape and sinusoidal currents in order to get optimal torque quality• usually overlapped stator windings• mostly skewed surface permanent magnets in rotor• complex, cost-intensive high-resolution rotor position sensors like encoder or resolver (or sensorless methods) are mandatory for the sinusoidal current control• at least two current sensors are necessary to impose the shape of the phase currents
Due to the low torque ripple sinusoidal PMSM drive is the only proper technology for high performance applications
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PMSM drives technologies BLDC motors and drives
• trapezoidal back-EMF shape and trapezoidal current in order to get good torque quality• usually concentrated stator windings• surface mounted permanent magnets (rings or segments)• BLDC motors are driven in two-phase-on mode• a simpler rotor position sensor, with a resolution of six instants per electrical period, may be used for the commutation• a single current sensor is needed for a possible control of the current in the two motor phases
The torque pulsations can be high due the current commutation and back-EMF shapes with remarkable distortions. This simple control strategy is very often employed in low performance applications, where the required torque quality is not too high.
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PMSM drives technologies PMSM design
PMSM with single-layer concentrated windings
Motor design – selection of the motor topology based on a quality factor (taking into account the cogging torque behaviour and the magnitude of the winding factor of the mmf-fundamental)
PMSM with two-layer concentrated windings
Quality factors for small PMSM (up to 24 stator slots and 16 rotor poles)
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PMSM design aspectsMaterials for active components of PMSM
• Permanent magnets (manufactured by injection/compression moulding/ sintering)
• ferrites• Neodymium-Iron-Boron (NdFeB)
For high torque density applications only sintered NdFeB-magnets
• Soft magnetic materials• cold rolled magnetic lamination (CRML) steel• soft magnetic composites (SMC) for “3-D design” and manufacturing capabilities
Conventional lamination steel is mandatory for high torque density applications
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PMSM design aspectsConstruction and manufacturing technologies for PMSM – winding systems
Transition from conventional overlapped to non-overlapped (concentrated, tooth-wound) winding systemsQ=12, m=3, 2p=4 Y||
1 2 3 4 5 6 7 8 9 10 11 12
U V W
We Ue Ve Ua Va Wa
Q=6, m=3, 2p=4 Y||
Va Ue VeWe
1 2 3 4 5 6
Ua Ua UeUe VeVa Va VeWeWa WaWe
Ua Wa
• conventional overlapped winding
• non-overlapped (concentrated, tooth-wounded) windings
• short end turns of the concentrated winding lead to a reduction of the copper losses• needle winding technology offers major advantages for coils with lower number of turns and higher wire diameter, like in PMSM for automotive applications
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PMSM design aspectsConstruction and manufacturing technologies for PMSM – modular stators
New modular stator solutions (in order to increase the slot fill factor, especially for coils with higher wire diameter)
• teeth and yoke stator segments• two-part stators• rolled stator
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Fundamental control issues
• Accurate stator current synchronization with the rotor position is mandatory for good quality torque
Basic configuration of a drive system with a three-phase PMSM - used for both types of PMSM
• Rotor position feedback• trapezoidal PMSM-drive: three Hall-elements (with a resolution of 60 electrical degrees)• sinusoidal PMSM-drive: higher resolution rotor position sensor (encoder or resolver)
3phPMSMVDC
Drive power end
stage
Drive control
position feedback
currents feedback
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Motor control issuesControl strategies
• sinusoidal indirect current vector control
• trapezoidal current control
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Case studySinusoidal vs. trapezoidal PMSM for electric active front steering
EAFS-motor specification and design constraints
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Case studyBLAC drive - experimental results
The torque production
can be maximized through optimizing the torque angle γ
• torque vs. speed characteristics for different torque angle γ
• torque vs. torque angles for different phase currents
• torque pulsations
( )( ).23
qdqdqPMem IILLIpT −−= ψShaft output torque vs. torque angle
(variable phase current)
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
0 1000 2000 3000 4000 5000 6000 7000Speed [1/min]
Shaf
t out
put t
orqu
e [N
m]
T2_gamma = 0T2_gamma = 20T2_gamma = 40T2_gamma = 60
Shaft output torque vs. torque angle and phase current
0.000
0.200
0.400
0.600
0.800
1.000
1.200
1.400
1.600
0 10 20 30 40 50 60 70 80 90
Torque angle [deg_el]Sh
aft o
utpu
t tor
que
[Nm
]
6.6 Arms
19.7 Arms
32.6 Arms
45.6 Arms
71.3 Arms
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Case studyBLDC drive - experimental results
• BLDC motor mounted together with servo drive and torque transducer
• measured torque-speed characteristics for different advance angle values
• measured torque pulsations for the BLDC motor
0
100
200
300
400
500
600
700
800
900
1000
0 500 1000 1500 2000 2500 3000 3500 4000 4500
Drehzahl(rpm)
Dre
hmom
ent(N
m)
Adv=0 Adv=10 Adv=20 Adv=30
0 5 10 15 20 25 300
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Rotor pos ition [deg mech]
Tor que [Nm ]
Torque vs . Rotor pos ition
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Conclusion
• Aim of this presentation
• overview of high performance automotive electric drives• typical specification• key performance parameters• proper candidates
• overview of permanent magnet synchronous motors technology• BLAC drive have the lower pulsating torque and the best acoustical behaviour but the control structure is more complex than in the case of the trapezoidal drive, as it requires the presence of a more expensive position sensor (encoder) in comparison with the 3 Hall sensors required in the trapezoidal drive and requires at least 2 current sensors • BLDC drive is more simple and only one current sensor could solve the current acquisitionissue resulting in much lower costs of the drive, but has higher current peaks (higher current from the DC supply and higher torque pulsations
Dr. Dorin ILES ([email protected]) FISITA 2008September 14-19, Munich, Germany
Thank you for your attention!